RU2728681C1 - Method of standardizing measurements in ultrasonic two-dimensional shear-oedal elastography - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine, particularly to ultrasonic elastographic diagnostics of liver disease. Method of standardizing the measurement site in the ultrasonic two-dimensional shear elastography of the liver involves obtaining an image and selecting an area of study by means of a convective ultrasonic sensor in B-mode, installed in the right lobe of the liver through one of the intercostals with the patient's position on the back with the maximum right arm displacement and in short for 4–5 s of the breath delay, adjustment of the color scale range of elasticity when the two-dimensional elastography mode for the study area is switched on, fixation of the elastogram in the study area and carrying out in the field of the shear wave or elasticity measurement of the hepatic tissue measurement, wherein during adjustment the range of the color scale of elasticity is narrowed to 15 kPa to obtain a visual appearance on the elastogram in the study area of the vertical strips, said elastogram is recorded, and maximum shear wave velocity or hepatic tissue elasticity is measured in vertical strip section.

EFFECT: invention enables reducing number of errors and improving accuracy of differential assessment of fibrosis stages.

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Description

The invention relates to medicine, in particular to ultrasound elastographic diagnosis of liver disease and relates to a method for reducing the number of diagnostic errors in determining the stage of fibrotic liver damage.

In clinical practice, the known methods for diagnosing liver fibrosis are ultrasound methods that use the assessment of the speed of propagation of shear waves in the liver tissues. Registration of their speed makes it possible to judge the elasticity of the hepatic parenchyma, depending on the amount of connective tissue (fibrosis), since the speed of shear waves and the elasticity of the tissues in which they propagate are related by the equation E = p3C ² (where E is elasticity in kPa, p is the density of tissue, taken as 1, and C is the shear wave velocity expressed in meters per second).

For the ultrasound assessment of liver fibrosis, the method of "transient elastography" (TE) is known using the "Fibroscan" ultrasound apparatus (Echosens, France). [Mueller S., Sandrin L, Liver stiffness: a novel parameter for the diagnosis of liver disease, Hepatic Medicine: Evidence and Research 2010: 2 49-67], with a combined transducer consisting of a built-in vibrator mechanically generating shear waves, and an ultrasonic transducer capable of tracking the speed of their propagation.

Elastometry on "Fibroscan" is performed in one of the intercostal spaces of the right lobe of the liver in the patient's supine position, with the right hand thrown back behind the head to maximize the expansion of the intercostal space. Liver elasticity is automatically assessed based on shear wave velocity measurements in an unchanged ROI (ROI).

This method has a certain number of disadvantages: the operator does not directly see the measurement site and judges the quality of the study only by the shear full propagation schedule; conducting a study using a rather bulky sensor with a vibrator can be difficult or even impracticable in patients with narrow intercostal spaces; fixed ROI depth makes it difficult or even impossible to perform elastometry in patients with severe obesity; since shear waves do not propagate through the fluid, assessment of liver fibrosis in patients with ascites is not possible. As a result, the listed disadvantages lead to the fact that often the measurements of the elasticity of the liver on "Fibroscan" cannot be performed for technical reasons and, even when receiving valid data, there is a noticeable scatter and a noticeable number of both false-positive and false-negative results.

For ultrasound assessment of liver fibrosis, the method of single point shear wave elastography (1pSWE or ARFI elastography) is also known [Nightingale K, Soo MS, Nightingale R, Trahey G., Acoustic radiation force impulse imaging: in vivo demonstration of clinical feasibility, Ultrasound Med Biol. 2002 Feb; 28 (2): 227-35]. The shear wave in this method is generated not on the surface, but deep in the liver tissue using a special “Amplified Acoustic Impulse” or ARFI (acoustic radiation force impulse) in the region of interest (ROI).

Elastometry using single-point shear wave elastography is performed in the same way as for "transient elastography", however, in contrast to "transient elastography", the area of investigation (ROI) is located by the physician-researcher already in a randomly selected area of the parenchyma of the right lobe, selected by him during standard ultrasound of the liver in B-mode.

Single point shear wave elastography cannot interfere with ascites, because shear waves are generated already inside the liver parenchyma, and not on the body surface. Of great importance to the quality of measurements is the operator's ability to visually assess the structure of the liver and select a location for the ROI.

The disadvantage of point shear wave elastography is the impossibility of identifying artifacts in the ROI, such as pulsating vessels, reverberations, or the absence of signals about shear wave propagation, which leads to noticeable heterogeneity of the elastometry results.

The closest analogue (prototype) is two-dimensional shear wave elastography of the liver (2D SWE) [Bavu E, Gennisson JL, Couade M, Bercoff J, Mallet V, Fink M, Badel A, Vallet-Pichard A, Nalpas B, Tanter M, Pol S. , Noninvasive in vivo liver fibrosis evaluation using supersonic shear imaging: clinical study on 113 hepatitis C virus patients. Ultrasound in Med. & Biol., Vol. 37, No. 9, pp. 1361-1373].

The method of 2D shear wave elastography is also based on the use of "Amplified Acoustic Impulse" (ARFI), however, not one such pulse is used, but a successive, at different depths, a series of several shock pulses that create a lateral front of shear waves. To increase the area of study (ROI) in two-dimensional shear wave elastography, several (3-4) such sequences are created in a row. The advancement of all fronts is remembered and makes it possible to form a two-dimensional map of the distribution of the shear wave velocity or the elasticity of the liver tissue in the ROI. Moreover, all shades of the card are associated with a certain speed or elasticity.

Liver elastometry using two-dimensional shear wave elastography is also performed according to the generally accepted scheme for liver elastography, however, unlike single-point shear wave elastography, the operator, starting the elastography program, waits for the ROI staining to become stable, without artifacts, and only after that “freezes »Image and with the help of a special measuring window inside the ROI measures the velocity or elasticity in the most homogeneous signal region.

Elastometry using two-dimensional shear wave elastography has a number of obvious advantages, including a larger area of study (ROI) than in single-point shear wave elastography and the ability to select a stable image, by the quality of which the operator judges the validity of subsequent measurements.

The main disadvantage of the prototype is the problem associated with a certain subjectivity of the use of the measuring window in the study area (ROI): sometimes two or three small measuring windows are used, but more often - one large one with an estimate of the average velocity (or elasticity) in it, as in the example in Fig. 1. In the presented image, the average value of the elasticity of the liver in the large round measuring window is 8.5 kPa, which corresponds to the stage of fibrosis F2-3 on the Metavir scale, however, other elasticity indicators are obviously present in the same window - the minimum is 5.4 kPa, which is normal, and the maximum - 12.1 kPa, indicating the stage of fibrosis F4.

The reason for such discrepancies has not been described in the literature.

The technical result of the invention is the standardization of the measurement site - elastometry (elasticity measurement) or velocimetry (shear wave velocity measurement) - on an ultrasonic two-dimensional shear wave elastogram, which leads to a decrease in the number of errors and increases the accuracy of the differential assessment of fibrosis stages in comparison with the prototype.

The technical result is achieved due to the fact that the Method for standardizing measurements in ultrasonic two-dimensional shear wave elastography, including the following main stages of the prototype, namely: measuring the elasticity of the liver with a conventional convex ultrasound transducer in the right lobe of the liver through one of the intercostal spaces when the patient is supine with maximum abduction of the right hand and during a short breath holding for 4-5 seconds; the choice of the study area using the B-mode differs in that the following new stages are included: before turning on the two-dimensional elastography, the range of the color scale narrows until the visual appearance of vertical stripes in the study area, indicating the presence of one or more fronts of shear waves; the elastogram is "frozen" only after the stable appearance of these bands; measurements are carried out only in the area of the stripes, using only the maximum values of speed or elasticity for interpretation.

Brief description of figures and drawings:

FIG. 1. Two-dimensional shear wave elastogram of the liver

FIG. 2. Two-dimensional shear wave elastogram of the liver of a patient with liver cirrhosis

FIG. 3. Two-dimensional shear wave elastogram of the liver of a patient with verified liver fibrosis F3.

FIG. 4. Two-dimensional shear wave elastogram of the liver of a patient with liver cirrhosis.

FIG. 5. Two-dimensional shear wave elastogram of the phantom in the modes of wide (a) and narrowed (b) ranges of the color scale (in the upper right corner of the elastograms)

Achievement of technical results is demonstrated by specific examples.

Example 1. Patient B-in, 52 years old, with liver cirrhosis (pronounced ascites, dilated veins of the esophagus). When measured in the strip (Fig. 1), the elasticity of the liver averaged 16 kPa, which indicates F4 fibrosis according to Metavir, while measurement outside the strip (average 9.8 kPa) indicates only the stage of F3 fibrosis according to Metavir.

Example 2. Patient Mr., 48 years old, with liver fibrosis F3 according to Metavir, verified by biopsy. When measured in a strip (Fig. 2), the elasticity of the liver averaged 9 kPa, which indicates F3 fibrosis according to Metavir. The out-of-band measurement (FIG. 3) averaged only 7.2 kPa, indicating only the Metavir F2 fibrosis stage.

Example 3. Patient T-th, 60 years old, liver cirrhosis (ascites, enlarged veins of the esophagus). When measured in a wide band (Fig. 4), the elasticity of the liver averaged 31.7 kPa, when measured outside the band, an average of 16.3 kPa. In both cases, we are talking about cirrhosis, but this difference is fundamental, since underestimation of the result is dangerous by missing a serious complication - portal hypertension, which usually manifests itself after 20-25 kPa.

The reason for the scatter in the results of digital values when conducting two-dimensional shear wave elastography lies in the use of only the standard range of the color scale, wide enough to hide the features of the propagation of shear waves in tissues. For example, in FIG. 5 shows the measurement of phantom elasticity using a large meter and over a wide range (0 to 125 kPa) of the scale, at which the staining of the study area appears to be completely homogeneous. The average elasticity of the phantom tissue (13.1 kPa) differs markedly from the minimum (11.4 kPa) and maximum (16.1 kPa) values, although in this case we are talking about a phantom with an isotropic tissue structure. However, if the scale range is significantly narrowed (in this case, to 0-15 kPa), then dark vertical stripes begin to clearly appear on the elastogram of the same phantom, the appearance of which is easily explained by the previously described feature of creating several successive vertical shear wave fronts. The initial amplitude of the shear wave has a maximum value, which makes its advance most noticeable, but at a certain distance from the site of excitation, the amplitude of tissue displacement dies out and the accuracy of velocity measurements is noticeably reduced. In the example shown in Fig. 5b example, the elasticity in the strip ranges from 14.3 to 15.6 kPa, between the strips - already from 12.7 to 13.5 kPa. Therefore, it is obvious that the most adequate assessment of the velocity or elasticity of the tissue will be only when measuring in the zone of stripes - at the place of birth of shear waves.

Claims (1)

A method for standardizing the measurement site in the study area when carrying out ultrasound two-dimensional shear elastography of the liver, including image acquisition and selection of the study area using a convex ultrasound probe in B-mode installed in the right lobe of the liver through one of the intercostal spaces when the patient is supine with maximum abduction of the right hands and during a short breath hold for 4-5 seconds, adjusting the range of the elasticity color scale when the two-dimensional elastography mode is turned on for the study area, fixing the elastogram in the study area and conducting measurements of the shear wave velocity or the elasticity of the liver tissue in the study area, characterized in that when adjusting, the range of the elasticity color scale is narrowed to 15 kPa until a visual appearance on the elastogram in the study area of vertical stripes is obtained, the specified elastogram is recorded and the maximum shear wave velocity is measured, or elasticity of the liver tissue in the area of the vertical strip.

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